Your search keyword '"Housheng Zhou"' showing total 2 results

1. A Robust and Energy-Efficient Train Timetable for the Subway System

Author

Lixing Yang, Liu Pei, Joris Wagenaar, Qingxia Kong, Marie Schmidt, Ziyou Gao, Housheng Zhou, Department of Technology and Operations Management, Public Transport, Econometrics and Operations Research, and Research Group: Operations Research

Subjects

050210 logistics & transportation, Mathematical optimization, Crowding in, train timetable, Efficient algorithm, Computer science, 05 social sciences, Transportation, robustness, 010501 environmental sciences, subway system, 01 natural sciences, Computer Science Applications, Regenerative brake, Robustness (computer science), 0502 economics and business, Automotive Engineering, Train, Total energy, energy efficiency, energy storage device, Variable neighborhood search, 0105 earth and related environmental sciences, Civil and Structural Engineering, Efficient energy use

Abstract

In the subway system, passenger crowding in peak hours is likely to cause train delays that easily propagate to following trains, resulting in a lower efficiency of the system. Consequently, this paper focuses on determining a robust timetable for the trains on the one hand, i.e., finding a better timetable to avoid delay propagation as much as possible in case of a crowded subway system. On the other hand, this paper considers the energy efficiency, i.e., reducing the total energy consumption during operations by selecting appropriate speed profiles and maximizing the utilization of regenerative braking energy. A related mathematical optimization model is formulated with the objective of maximizing the robustness and minimizing the total energy consumption. In order to solve this model, an efficient algorithm, i.e., simulation-based variable neighborhood search algorithm, is presented to obtain a good timetable in reasonable amount of time. Finally, experiments are implemented to show the performance of the proposed algorithm.

Published

2020

2. Train timetabling with dynamic and random passenger demand: A stochastic optimization method

Author

Congcong Gong, Jungang Shi, Yanhui Wang, Hanchuan Pan, Chen Dewang, Housheng Zhou, and Lixing Yang

Subjects

050210 logistics & transportation, Commercial software, Mathematical optimization, Urban rail transit, Computer science, 05 social sciences, Transportation, Time horizon, 010501 environmental sciences, Management Science and Operations Research, 01 natural sciences, 0502 economics and business, Automotive Engineering, Headway, Stochastic optimization, Integer programming, Variable neighborhood search, Randomness, 0105 earth and related environmental sciences, Civil and Structural Engineering

Abstract

Considering the dynamics and randomness of passenger demand, this paper investigates a train timetabling problem in the stochastic environment for an urban rail transit system. With the scenario-based representation of passenger distribution, an integer nonlinear programming (INLP) model is first formulated to simultaneously optimize the total number of train services, headway settings and speed profile selection decision during the planning time horizon, in which the expected total service cost is treated as the objective function. Through an analysis of the features of the nonlinear constraints, a reformulation method is proposed to develop an equivalent integer linear programming (ILP) model that can be easily solved by commercial software. Moreover, a variable neighborhood search algorithm is developed to find the approximate optimal solutions for large-scale problems within the tolerable computing time. Finally, two sets of numerical experiments, with the operation environments of a simple urban rail transit line and Fuzhou Metro Line 1, are implemented to verify the solution quality and effectiveness of the proposed methods.

Published

2021